Dual generator single power source for tandem pool and spa

ABSTRACT

A sanitizer generation system supplies power to a first and a second sanitizer generator. Each of the sanitizer generators is connected to a body of water by a circulation system. The system includes a power supply and a control system connected to the power supply and the sanitizer generators. The control system selectively delivers electric current from the power supply to the first and second sanitizer generators.

CROSS-REFERENCE TO RELATED APPLICATION(S)

The present application is related to the concurrently filed application Ser. No. ______, “Automated Electrolyte Addition for Salt Water Pools, Spas, and Water Features” and Ser. No. ______, “Pool and Spa Dual Body Sanitization.”

BACKGROUND OF THE INVENTION

The present invention relates to systems and methods for sanitizing pools and spas. In particular, the present invention relates to a single power source system for generating a sanitizer for a tandem swimming pool and spa.

Pools and spas have a circulation system that continually pumps water from the pool or spa through a filter, heater, and sanitizer feed system before returning the water back to the pool or spa. The circulation system is necessary to maintain the body of water at sanitary conditions. The water passes through the filter to reduce the accumulation of foreign material, such as hair, soil, or solids, in the pool or spa. Once the water has been filtered, the water passes through the heater, where the water is heated prior to returning to the pool or spa.

In addition to filtering, pool and spa water also requires regular sanitization in order to maintain hygienic conditions. Allowing sanitation levels to either fall below or rise above required specifications results in decreased efficiency of the system. Low levels of chemical sanitizer in the pool or spa can contribute to algae blooms, bacterial breakouts, cloudiness in the water, and chemical imbalances. A method for sanitizing pool or spa water is by adding sodium chloride (NaCl) to the pool or spa and passing the water containing sodium chloride through a chlorine generator where electrolysis converts the sodium chloride and water to sodium hypochlorite (NaOCl), by the following reaction: 2NaCl(aq)+2H₂O→Cl₂(g)+H₂(g)+2NaOH (aq)→NaOCl(aq)+H₂O+NaCl(aq)+H₂(g).

The chlorine generator is capable of being powered on and off depending on the concentration of chlorine in the water. When there is a sufficient level of chlorine in the pool or spa water, the chlorine generator is powered off and no reaction takes place. Thus, water circulating through the circulation system is filtered and heated, but the composition of the water is not altered. When the level of chlorine has fallen to a desired setpoint, the chlorine generator is powered on and the sodium chloride and water passing through the chlorine generator is converted to sodium hypochlorite. The chlorine generator remains powered on until the concentration of chlorine in the water has reached a desired steady state level.

Oftentimes, both a swimming pool and a spa are installed. Typically, the volume of the pool is on average ten to fifteen times larger than the volume of the spa. Despite this large difference in volumes, the cost of the equipment for treating the pool and spa is not significantly different. The need for two power sources, one supplying power to generate chlorine for the pool and the other supplying power to generate chlorine for the spa, can result in higher installation and maintenance costs for the tandem pool and spa.

BRIEF SUMMARY OF THE INVENTION

A sanitizer generation system supplies power from a single source to a first and a second sanitizer generator. Each of the sanitizer generators is connected to a body of water by a circulation system. The system includes a power supply and a control system connected to the power supply and the sanitizer generators. The control system selectively delivers electric current from the power supply to the first and second sanitizer generators.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram of a dual generator single power source system in accordance with the present invention.

DETAILED DESCRIPTION

FIG. 1 is a schematic diagram of sanitizer generation system 10 in accordance with the present invention. Sanitizer generation system 10 is a dual sanitizing generator, single power source system that maintains the sanitizer concentration in two bodies of water, such as pool 12 a and spa 12 b, at a desired level by generating sanitizer for both bodies of water with a single power source. Pool 12 a and spa 12 b may be any combination of bodies of water to be treated. Using a single power source to generate sanitizer for two bodies of water that are in close proximity to one another is beneficial for reducing the cost of maintaining such systems by as much as 42%.

Sanitizer generation system 10 is connected to pool sanitizer generator 14 a and to spa sanitizer generator 14 b by pool circulation system 16 a and spa circulation system 16 b, respectively, and generally includes power supply system 18 and control system 20. Power supply system 18 supplies electric current to sanitizer generation system 10 from an alternating current (AC) supply 22 and includes power supply box 24, transformer box 26, and rectifier box 28. Control system 20 includes pool flow switch FSW_(a), spa flow switch FSW_(b), pool relay coil C_(a) and contacts C1 _(a) and C2 _(a), spa relay coil C_(b) and contacts C1 _(b) and C2 _(b), and controller 30.

Sanitizer generation system 10 maintains the concentration of sanitizer in pool 12 a and spa 12 b at a desired level by powering sanitizer generators 14 a and 14 b on and off as needed. When the level of sanitizer concentration in pool 12 a falls to a desired setpoint, pool sanitizer generator 14 a is powered on to generate sanitizer for pool 12 a. Likewise, spa sanitizer generator 14 b is powered on when the level of sanitizer concentration in spa 12 b reaches a minimum level in order to generate more sanitizer for spa 12 b.

Pool circulation system 16 a runs continuously and includes piping 32 a, circulation pump 34 a, filter 36 a, heater 38 a, sensor 39 a, side stream 40 a, flow switch FSW_(a), and sanitizer generator 14 a. Circulation system 16 a connects pool 12 a to sanitizer generator 14 a and operates independently of pool and spa sanitizer generators 14 a and 14 b. When there is a sufficient level of sanitizer in pool 12 a, sanitizer generator 14 a is powered off and water flows through sanitizer generator 14 a without being reacted. When sanitizer is needed, sanitizer generator 14 a is powered on while circulation system 16 a transports water from pool 12 a through sanitizer generator 14 a and transports sanitized water back to pool 12 a. Circulation pump 34 a is typically positioned immediately downstream from pool 12 a and pumps water from pool 12 a through piping 32 a and side stream 40 a.

Side stream 40 a of circulation system 16 a includes sanitization inlet line 42 a and sanitization outlet line 44 a. Water enters sanitizer generator 14 a through sanitization inlet line 42 a and leaves sanitizer generator 14 a through sanitization outlet line 44 a. Sanitization inlet line 42 a is plumbed to piping 32 a between filter 36 a and heater 38 a and connects pool 12 a to sanitizer generator 14 a. When sanitization inlet line 42 a branches from piping 32 a, some of the water flowing through piping 32 a is diverted into sanitization inlet line 42 a at a flow rate lower than the flow rate of the water flowing through piping 32 a.

Because a pump is not plumbed to side stream 40 a, a pressure drop is required across circulation system 16 a to maintain the flow of water in side stream 40 a at a velocity sufficient to pass the water through sanitizer generator 14 a and back to pool 12 a. To create a pressure drop across circulation system 16 a, sanitization inlet line 42 a is plumbed to piping 32 a immediately after filter 36 a. Positioning sanitization inlet line 42 a downstream from filter 36 a and upstream from sanitizer generator 14 a also ensures that only a minimal amount of foreign material present in the water enters sanitizer generator 14 a. Without filter 36 a, foreign material could accumulate inside sanitizer generator 14 a and reduce the life and performance of sanitizer generator 14 a.

Alternatively, sanitization inlet line 42 a may also be plumbed to piping 32 a immediately after circulation pump 34 a. However, although positioning sanitization inlet line 42 a between circulation pump 34 a and filter 36 a would provide an adequate pressure drop across circulation system 16 a, the water entering sanitizer generator 14 a would be unfiltered. Thus, installation of an in-line strainer with a small mesh in sanitization inlet line 42 a would be necessary to reduce build-up of foreign material in sanitizer generator 14 a.

Pool flow switch FSW_(a) is plumbed to circulation system 16 a at sanitization inlet line 42 a and senses water flow from piping 32 a through sanitization inlet line 42 a. Flow switch FSW_(a) serves as a failsafe for sanitizer generation system 10. Sanitizer generator 14 a is only capable of being powered on if flow switch FSW_(a) senses water flow through pool sanitization inlet line 42 a. If flow switch FSW_(a) does not sense water flow through sanitization inlet line 42 a, flow switch FSW_(a) will not close and power is not supplied to sanitizer generator 14 a.

The water leaves sanitizer generator 14 a at sanitization outlet line 44 a, which connects to piping 32 a downstream from heater 38 a so that the water from sanitization outlet line 44 a and the water from pool piping 32 a combine prior to entering pool 12 a.

Spa circulation system 16 b includes piping 32 b, circulation pump 34 b, filter 36 b, heater 38 b, sensor 39 b, side stream 40 b, and flow switch FSW_(b) and functions in the same manner as pool circulation system 16 a.

Sanitizer generators 14 a and 14 b are electrolytic cells that produce sanitizer from the water and electrolyte pumped through side streams 40 a and 40 b when sanitizer generators 14 a and 14 b are powered on, respectively. The water from pool 12 a and spa 12 b circulating through circulation systems 16 a and 16 b typically contain electrolyte that has been added to pool 12 a and spa 12 b. When there is a sufficient level of sanitizer in pool 12 a and spa 12 b, sanitizer generators 14 a and 14 b are powered off and the water and electrolyte pass through without being reacted. In one embodiment, sanitizer generators 14 a and 14 b are watertight tubes containing titanium plates coated with a precious metal. Although sanitizer generators 14 a and 14 b are shown in FIG. 1 as being plumbed in parallel with heaters 38 a and 38 b, sanitizer generators 14 a and 14 b may also be plumbed in-line with heaters 38 a and 38 b without departing from the intended scope of the present invention.

In an exemplary embodiment, pool and spa sensors 39 a and 39 b are connected to pool and spa circulation systems 16 a and 16 b, respectively, and measure the oxidation-reduction potential (sanitizer concentration) of the water passing through circulation systems 16 a and 16 b. Sanitizer generation system 10 is at steady state and sanitizer generators 14 a and 14 b are powered off when the sensed parameter (e.g. oxidation-reduction potential, pH, or conductivity) of the water in circulation systems 16 a and 16 b is at a desired level. When the sensed parameter of the water in pool 12 a reaches a desired setpoint, sensor 39 a communicates to controller 30 that pool 12 a needs sanitization. Likewise, when the sensed parameter of the water in spa 12 b reaches a desired setpoint, sensor 39 b communications to controller 30 that spa 12 b needs sanitization.

Controller 30 is in communication with sensors 39 a and 39 b and is connected to power supply source 18 and relay coils C_(a) and C_(b) through pool sanitization enable 46 a and spa sanitization enable 46 b. Pool sanitization enable 46 a enables plug 50 a. Spa sanitization enable 46 b enables plug 50 b. In one embodiment, controller 30 is an Acu-Trol AK2100D controller with the capability to monitor oxidation-reduction potential.

Pool sanitizer generator 14 a can only be activated if two conditions are met: (1) sensor 39 a communicates to controller 30 that sanitizer is needed in pool 12 a, and (2) flow switch FSW_(a) senses that there is water flow through pool sanitization inlet line 42 a. If both conditions are met, controller 30 supplies electric current to pool enable plug 50 a. Current is supplied to pool enable plug 50 a through power enable outlet 46 a. AC supply box 22 provides an alternating current to power supply system 18. Power supply box 24 houses a primary transformer, current driver, and main relay switch. Transformer box 26 converts the alternating current to the voltage required to run sanitizer generators 14 a and 14 b. Rectifier box 28 converts the alternating current to a direct current and houses a rectifier set, cooling block, and mechanical relay set.

Current is supplied to pool enable plug 50 a via outlet 46 a to energize pool relay coil C_(a). When energized, pool relay coil C_(a) closes pool relay contacts C1 _(a) and C2 _(a), allowing electric current from power supply system 18 to reach pool sanitizer generator 14 a. Once pool sanitizer generator 14 a is powered on, the water and electrolyte entering pool sanitizer generator 14 a through pool sanitization inlet line 42 a is reacted and converted to a sanitizer solution.

In addition to controller 30 enabling pool sanitization enable plug 50 a, flow switch FSW_(a) must also sense water flow through pool sanitization inlet line 42 a for pool sanitizer generator 14 a to power on. When flow switch FSW_(a) senses water flow through pool sanitization inlet line 42 a, flow switch FSW_(a) closes and electric current passes through relay coil C_(a). If flow switch FSW_(a) does not sense water flow through pool sanitization inlet line 42 a, flow switch FSW_(a) remains open and sanitizer generator 14 a cannot be powered on even though pool enable plug 50 a is enabled. If electric current cannot reach transformer box 26 or relay coil C_(a), sanitizer generator 14 a cannot be activated.

Pool sensor 39 a continuously communicates the amount of sanitizer in the water in pool circulation system 16 a to controller 30. As sanitizer is added to the water in pool circulation system 16 a, the sanitizer level of the water increases. Once the sanitizer level of the water reaches a desired maximum level, there is a sufficient amount of sanitizer in pool 12 a and controller 30 cuts off electric current to pool sanitization enable plug 50 a. When pool sanitization enable plug 50 a is not enabled, pool relay coil Ca is de-energized, causing pool relay contacts C1 _(a) and C2 _(a) to open and cut off power to pool sanitizer generator 14 a.

Spa circulation system 16 b, spa flow switch FSW_(b), spa sensor 39 b, spa relay coil C_(b), spa relay contacts C1 _(b) and C2 _(b), and spa sanitizer generator 14 b function and interact with controller 30 in the same manner as pool circulation system 16 a, pool flow switch FSW_(a), pool sensor 39 a, pool relay coil C_(a), pool relay contacts C1 _(a) and C2 _(a), and pool sanitizer generator 14 a.

Sanitizer generation system 10 has the capability to supply power to sanitizer generators 14 a and 14 b simultaneously, or one at a time, depending on the needs of pool 12 a and spa 12 b. When only one of sanitizer generators 14 a and 14 b is activated, full power is sent to the activated generator from power supply system 18. When sanitizer generators 14 a and 14 b are activated simultaneously, the power sent to each generator 14 a and 14 b is split. Thus, the output of each generator 14 a and 14 b is also reduced. Although FIG. 1 depicts sanitizer generators 14 a and 14 b as being equal in size, sanitizer generators 14 a and 14 b may also be sized depending on the desired output. Because pool 12 a is typically much larger than spa 12 b, pool 12 a generally requires more sanitizer than spa 12 b. Thus, it may be more effective for pool sanitizer generator 14 a to be larger than spa sanitizer generator 14 b. In addition, although FIG. 1 discusses a single power source sanitizer generation system supplying power to two bodies of water, the sanitizer generation system can supply power to more than two bodies of water without departing from the intended scope of the present invention.

Although the present invention is discussed using an automated system to activate and deactivate pool and spa sanitizer generators 14 a and 14 b, sanitizer generation system 10 can also be run manually, without a controller. Power is supplied to sanitizer generation system 10 at a level such that both pool and spa sanitizer generators 14 a and 14 b run continuously. While power is continuously supplied to sanitizer generation system 10, it is supplied at a trickle in order to avoid over-chlorination of either pool 12 a or spa 12 b.

The sanitizer generation system of the present invention provides a single power source for activating more than one sanitizer generator in order to reduce the cost of maintaining the sanitizer concentration of multiple bodies of water at a desired level. The sanitizer generation system is capable of supplying power to either only one sanitizer generator at a time, or to more than one sanitizer generator at a time. When a sensor in a circulation system circulating water from a body of water communicates to a controller that the sanitizer concentration in the body of water needs to be increased, the controller enables a pool sanitization enable plug to supply electric current through a power supply to the sanitizer generator connected to the body of water. The electric current provides the power necessary to run the sanitizer generator.

In addition to a need for sanitizer, a flow switch in the circulation system must also sense water flow through the circulation system in order for the sanitizer generator to be powered on. If the flow switch senses water flow in the circulation system, electric current passes through the power supply and energizes a relay coil. When the relay coil is energized, it closes a pair of relay contacts and allows electric current flowing from the power supply to reach the sanitizer generator. Once the sanitizer concentration in the body of water has reached a desired maximum level, the controller cuts off electric current to the enable plug, which de-energizes the relay coil, causing the relay contacts to open. When the relay contacts are open, no power is supplied to the sanitizer generator. If at any time the flow switch does not sense water flow through the circulation system, the flow switch is opened and electric current cannot reach the sanitizer generator.

Although the present invention has been described with reference to preferred embodiments, workers skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the invention. 

1. A system for supplying power to a first sanitizer generator and a second sanitizer generator, wherein the first sanitizer generator is connected to a first body of water by a first circulation system, and wherein the second sanitizer generator is connected to a second body of water by a second circulation system, the system comprising: (a) a power supply for providing electric current to the first sanitizer generator and the second sanitizer generator; and (b) a control system connected to the power supply, the first sanitizer generator and the second sanitizer generator for selectively delivering electric current from the power supply to the first and second sanitizer generators.
 2. The system of claim 1, and further comprising a first sensor located in the first circulation system, wherein the first sensor senses a parameter related to a sanitizer level in the water of the first body of water.
 3. The system of claim 2, and further comprising a second sensor located in the second circulation system, wherein the second sensor senses a parameter related to a sanitizer level in the water of the second body of water.
 4. The system of claim 3, wherein the control system selectively delivers electric current to the first sanitizer generator based upon a signal from the first sensor.
 5. The system of claim 4, wherein the control system selectively delivers electric current to the second sanitizer generator based upon a signal from the second sensor.
 6. The system of claim 5, wherein the control system comprises: (a) a first flow sensor for sensing water flow through the first sanitizer generator; (b) a second flow sensor for sensing water flow through the second sanitizer generator; and (c) a control circuit connected to the power supply, wherein the control circuit controls delivery of electric current to the first sanitizer generator based on whether water flow is sensed by the first flow sensor, and wherein the control circuit controls delivery of electric current to the second sanitizer generator based on whether water flow is sensed by the second flow sensor.
 7. The system of claim 1, wherein the control system comprises: (a) a first relay for controlling flow of current between the power supply and the first sanitizer generator based on need for sanitizer in the first body of water and water flow in the first sanitizer generator; and (b) a second relay for controlling flow of current between the power supply and the second sanitizer generator based on need for sanitizer in the second body of water and water flow in the second sanitizer generator.
 8. A sanitizer generation system for treating water from a plurality of bodies of water, the system comprising: (a) a plurality of sanitizer generators, each sanitizer generator connected to receive water from one of the bodies of water; (b) a power supply; and (c) a control system connected to the power supply and the plurality of sanitizer generators for selectively delivering electric current from the power supply to the plurality of sanitizer generators.
 9. The system of claim 8, and further comprising a plurality of sensors, wherein each sensor senses a parameter related to a need for sanitization of water in one of the bodies of water.
 10. The system of claim 9, wherein the control system selectively delivers electric current to the plurality of sanitizer generators based upon signals from the sensors.
 11. The system of claim 9, wherein the control system comprises: (a) a plurality of flow sensors, wherein each flow sensor senses water flow through one of the sanitizer generators; and (b) a control circuit connected to the power supply, wherein the control circuit delivers electric current to each sanitizer generator based on the need for sanitization of the body of water connected to that sanitizer generator and water flow sensed in that sanitizer generator.
 12. The system of claim 11, wherein the control circuit includes: (a) a plurality of relays, wherein each relay controls flow of current between the power supply and one of the sanitizer generators.
 13. An automated method of sanitizing a first body of water and a second body of water with electric current from a single power source, the method comprising: (a) circulating water from the first body of water through a first circulation system, the first circulation system having a first sanitizer generator; (b) circulating water from the second body of water through a second circulation system, the second circulation system having a second sanitizer generator; (c) sensing a parameter of the water in the first body of water related to a need for sanitization; (d) selectively delivering electric current from the power source to the first sanitizer generator to generate sanitizer for the first body of water when sanitization is needed; (e) sensing a parameter of the water in the second body of water related to a need for sanitization; and (f) selectively delivering electric current from the power source to the second sanitizer generator to generate sanitizer for the second body of water when sanitization is needed.
 14. The method of claim 13, and further comprising: (g) sensing the water flow through the first sanitizer generator; and (h) sensing the water flow through the second sanitizer generator.
 15. The method of claim 15, wherein selectively delivering electric current from the power source to the first sanitizer generator is based on the need for sanitization of the first body of water and whether there is water flow through the first sanitizer generator.
 16. The method of claim 15, wherein selectively delivering electric current from the power source to the second sanitizer generator is based on the need for sanitization of the second body of water and whether there is water flow through the second sanitizer generator.
 17. A method of sanitizing a first body of water and a second body of water with electric current from a single power source, the method comprising: (a) circulating water from the first body of water through a first circulation system, the first circulation system having a first sanitizer generator; (b) circulating water from the second body of water through a second circulation system, the second circulation system having a second sanitizer generator; and (c) delivering electric current from the power source to the first sanitizer generator and the second sanitizer generator.
 18. The method of claim 17, wherein the first and second sanitizer generators are different sizes.
 19. The method of claim 17, wherein electric current is delivered from the power source based upon a sensed need for sanitizer in the first and second bodies of water.
 20. The method of claim 17, wherein electric current is continuously delivered from the power source to both the first and the second sanitizer generators. 